JPS62114129A - Laser control system - Google Patents

Abstract

PURPOSE:To automate the test of a laser control circuit by adopting the constitution that a DA converter set so that a photodiode detection voltage at write power lighting represents a read power level controls the subtraction of the write power level current. CONSTITUTION:A photodiode (PD) current/voltage conversion section 12 is provided, which obtains a prescribed lighting power even when a laser diode (LD) having a specific characteristic is used. The light power of the LD unit 1 is controlled by using analog switches 13, 15 to turn on/off automatic control means 3, 5 and automatic power control means 8, 17. Then the control is executed by a DA conversion means at the read power level and by the setting value of DA conversion means 7, 14 at the write power level. Thus, the test of the laser control circuit is automated and even when the LD unit is replaced, the specified light power is attained for the control.

Description

[Detailed Description of the Invention] [Summary] A laser control method for a laser diode unit for an optical disk device, which adjusts the amount of laser light emitted from each laser diode unit having unique characteristics to be approximately constant. , a plurality of resistor groups are set using a dip switch or the like, and control is automatically performed to restore the fluctuation of the light emitting power level from the laser diode unit to the original value based on the setting values for the plurality of digital/analog conversion means. This makes it possible to simplify and automate testing of laser control circuits, reduce testing man-hours, and reduce costs.

[Industrial application field]

The present invention relates to an optical disk device that optically writes and reads data, and more particularly to a laser control method that controls the amount of laser light emitted from a laser diode so that it is always constant.

Optical disk devices, which are expected to be used as large-capacity external storage devices for information processing devices, are capable of high-density recording several times higher than conventionally used magnetic disk devices.

For recording data on an optical disk device, for example, a strong laser light amount (a light amount equivalent to 5 to 1 cm, this is called a write power level) emitted from a laser diode is used as a light beam on a recording film on an optical disk medium. This is done by irradiating the recording film as a material and creating holes (bits) through its thermal reaction (however, there is also a method of changing the crystalline state of the recording film).

On the other hand, data written on an optical recording medium is obtained by irradiating a recording film with a weak laser beam emitted from a laser diode (light intensity equivalent to about 1 II W, this is called the read power level) as a light beam. It can be read by the amount of reflected light.

In order to obtain a more stable write power level and read power level, the amount of light emitted by the laser diode used in this way is monitored by a photodiode, and the light emitting power of the laser diode is controlled by the monitored current. I try to control it.

Additionally, laser diodes have unique characteristics, and in order to be used for optical disk devices, adjustments must be made to accommodate the unique characteristics and settings must be made to obtain approximately constant write and read power levels. are doing.

It is expected that such settings and control to always obtain a constant write power level and read power level can be realized by a simple control method.

(Prior art and problems to be solved by the invention) Figure 3 is a block diagram explaining the conventional example, Figure 4 is a diagram explaining the relationship between the drive current of the laser diode and the amount of light emitted, and Figure 5 is the monitor. Each figure shows a diagram explaining the voltage.

Figure 3 shows the laser diode unit 1 of an optical disk device.
This circuit diagram shows a circuit that controls the drive of a laser diode (hereinafter referred to as L 1), a photodiode (hereinafter referred to as PD) that monitors the amount of light emitted from the LD, and a variable resistor to adjust the monitor current flowing through the PD to a predetermined voltage value during initial setting. The PD current adjustment unit 2 consists of an operational amplifier 31, fixed resistors R1, R2, and a capacitor C1, and detects the PD voltage taken out from the P-port current adjustment unit 2 and converts it into a digital/analog (hereinafter referred to as D/A). A read power level detecting section 3 sets and outputs a voltage corresponding to a read power level set in the converter 4, which is set in the converter 4. (Not)
A read power level current adjustment section 5, which is composed of a D/A converter 4, a transistor TRI, a wire ring, and a fixed resistor R3, adjusts the drive current so that the LD emits light at the read power level. A write power level current adjustment unit 6, which is composed of two transistors TR2 and TR3 and a fixed resistor R4, adjusts the drive current so that the LD emits light at the write power level, and a PD whose output power of the LD indicates the write power level. Microprocessor (not shown) in advance to voltage
D/A converter transistor T set by
R4 and fixed resistor R5, and the D/A converter 7
It consists of a write power level setting section 8 that sets the write power level current adjustment section 6 so that the LD outputs the write power level set at D, a transistor TR5, and a variable resistor RV2.
A write power level current difference section setting section 9 that sets the write power level current subtraction section 10 based on the output from the /A converter 7. Two transistors TI? 6,7. A write power level current subtraction unit 10 that subtracts the write power level current from the PD lightning current in which the write power level current is superimposed on the read power level current, an AND circuit AND, and two Zener diodes. D1.2, and write data (hereinafter referred to as write data)
Transistors TI? The level shift section 11 adjusts the biases of 2.3 and 6.7.

For example, when writing data, the current applied to the LD has a pulse waveform as shown in FIG. In addition, the vertical axis of FIG. 4 is the light emission amount of the LD (indicated in units of 1), the horizontal axis is the applied current to the LD (ILD), and the symbol (al is the characteristic curve of the LD,
The symbol 伽) indicates the write power level point, the symbol (C1) indicates the read power level point, the symbol - indicates the current level flowing through the LD when writing data, and the symbol R indicates the current level flowing through the LD when reading data.

At this time, the PD voltage obtained by monitoring the amount of light emitted from the LD with the PD has a waveform shown in FIG.

That is, the pulse waveform of the write power level (b)' is superimposed on the read power level (cl').

On the other hand, each LD has its own characteristics, and large fluctuations in the write power level and read power level output by the LD will have an adverse effect on data quality, so no matter what characteristics the LD has, Initial settings are performed in the PD current adjustment section 2 so that a substantially constant write power level and read power level are always obtained.

In other words, using a calibrated power meter, synchroscope, etc. in the completed state as an optical head (not shown), a variable resistor is set so that the output voltage of the PD will be a constant value when the LD emits light with a constant power. Adjust with RVl, and lock the variable resistor RVI to fix the current state.

In addition, the circuit shown in Figure 3 automatically controls the PD voltage when monitored by the PD by setting it to the read power level when the output power fluctuates due to changes in the LD characteristics due to, for example, LD deterioration or changes in ambient temperature. are doing.

For this purpose, if there is a write power level component, the write power level current subtraction unit 10 removes the write power level component, and the light emitting power is calculated based on the setting values set in the D/A converters 4 and 7. It has a function to automatically adjust.

Also when setting this automatic adjustment function according to a predetermined function, the step of adjusting with the variable resistor RV2 in the write power level current difference setting section 9 and locking the variable resistor RV2 to fix it in the state at that time. is required.

For this reason, in the conventional example shown in Fig. 3, it is difficult to automate these tests (tests for each printed board), and this becomes a factor that hinders the reduction of testing man-hours and costs.
There are problems such as not being able to change the LD unit l easily.

[Means for solving problems]

FIG. 1 shows a block diagram illustrating the invention in detail. This principle block diagram is the functional blocks 1 to 1 explained in Figure 3.
1 (however, excluding PD current adjustment section 2 < 5, it is replaced by PD current adjustment section 2, and includes a PD current/voltage conversion section 12 that converts the current flowing through the PD into voltage with a predetermined conversion ratio). , is located between the PD current/voltage converter 12 and the read power level detector 3, and the output value of the A/D converter 16 (output to a microprocessor, not shown) is the PD voltage indicating the read power level. While the D/A converter 4 is being set, an analog switch 13 turns off the output of the PD current/voltage converter 12 and stops functions such as read power level detection 3, and the output value of the A/D converter 16 is set to read. A D/A converter 14 sets a value to determine a PD voltage value that indicates a power level from a microprocessor (not shown), a write power setting section 8, and a write power level current difference section setting. The write power level current difference setting section 9 controls the operation of the write power level current difference setting section 9 while the output value of the A/D converter 16 indicates the PD voltage indicating the read power level. It is configured by adding an analog switch 15 that turns on, an A/LO converter 16 that sets the current PD voltage, and notifies the microprocessor.

Note that the first auto power control is performed by the read power level detection 3 and the read power level current adjustment section 5.
It is assumed that the write power level setting unit 8 and the write power level current difference setting unit 17 form a second auto power control.

[Effect]

A laser control circuit (first and second auto power control) that controls the amount of laser light emitted from each LD unit, each having its own characteristic curve, to always be constant.
When initializing the laser diode unit,
Set multiple resistor groups to a preset ratio using dip switches, etc., and set the P during light power emission.
Automating the testing of the laser control circuit by configuring to automatically and easily control the subtraction of the write power level current by a D/A converter having a set value such that the D voltage indicates the read power level; This makes it possible to reduce testing man-hours and costs, and further promote automation of control by the laser control circuit.

〔Example〕

The gist of the present invention will be specifically explained below with reference to an embodiment shown in FIG.

FIG. 2 shows a block diagram illustrating the invention in detail. Note that the same reference numerals indicate the same objects throughout the figures.

The PD current/voltage converter 12 in this embodiment includes fixed resistors R9 to R1 for converting the PO current into voltage at a predetermined ratio.
3 and a switch 21 (for example, a dip switch) that shorts each of the fixed resistors R9 to R12.

Short bars, analog switches, etc. However, in this embodiment, a ditub switch is used.

Fixed resistors R9 to R13 of the PD current/voltage converter 12 are set at the time of design. Further, the setting of the switch 21 is performed when assembling or testing the device. That is, as described above, since the LD light emission power and PD current differ for each LD unit 1, it cannot be used as is because of a large amount of error.

Therefore, the characteristic data at this time is measured in advance, and based on this characteristic data, the output voltage of the two ports (the value set in the ^/ro converter 16 after ^/D conversion) when emitting light with a constant power is The switch 21 determines the resistance values of the fixed resistors R9 to R12, which are weighted in advance to a constant value.

As a result, the relationship between the LD light emission power and the PD lightning voltage is determined such that, for example, the PD voltage is 0.5V for the light emission power of 1a+H. Further, since the light emitting power and the PD current have a 1:1 proportional relationship, when the light emitting power changes, a corresponding PD lightning voltage can be obtained.

The above is the content that is processed before the product is shipped, but the following processing is processing that is performed at the time of use on the user side, for example, when the power is turned on or when an optical disk is replaced.

A first auto power control (hereinafter referred to as PC) processing section that has a function of automatically adjusting the light emission power of the PD by feedback of the read power level (for example, the read power level detection section 3 and the read power level current adjustment section) 5, etc.), that is, when the light emitting power of the LD changes due to temperature rise, etc. (changes as shown by the dotted line in Figure 5), it works to reverse the change (the dotted line in Figure 5 returns to a solid line). Turn off the function of the first ^PC processing section (which works like this) using the analog switch 13.

Note that the analog switch 13 is turned on and off under the control of a microprocessor (not shown). Also, while the function of the first APC processing section is turned off with the analog switch 13, the D/D converter 16 converts the D/D voltage so that the PD lightning voltage indicates the specified power (approximately 1 mW) at the time of reading.
Configure the A converter 4.

The set value of the D/^ converter 4 is transferred to the transistor T via an operational amplifier 31 operating as a voltage follower.
Supplied to the base of the RI. As a result, the transistor TRI is turned on, and the emitter voltage becomes the voltage V[! F! 1
(VEt!2 also indicates the supply voltage), fixed resistor R3
By flowing the current determined by LD to the LD, the first ^
PC processing is performed.

Next, the operation of adjusting the light emitting power of the LD at the write power level will be explained. In this case, since a power level at which data can be written is output, the defocus is performed to such an extent that data cannot be written.

Since the light emission during data writing is subjected to pulse pulse modulation as shown in Figure 4, the PD lightning voltage is determined by the ratio of the pulse duty cycle.
When the duty is 50% with pulse emission of W (however, lead pad'7-1mW, 0.5V/mW), (((1(1)
++W -1slW)/2) +1mW) xo,s
=2.75V.

D so that the output of the A/D converter 16 becomes this value.
/^ The value of converter 7 is set by a microprocessor (not shown). Note that when changing the write power, this value is changed proportionally.

Next, a write power level current subtraction unit 10 that subtracts a PD current corresponding to write power level light emission is operated.

That is, the analog switch 15 is turned on (that is, the second APC consisting of the write power level current difference middle setting section 17, etc.) is turned on.
is turned on), and the set value of the D/^ converter 14 is determined so that the value of the A/D converter 16 indicates the PD lightning voltage at the read power level. In this embodiment, this voltage value is 0.5v.

Finally, the first PC processing section is turned on and the set value of the D7A converter 4 is adjusted again so that the output value of the A/D converter 16 becomes the read power level of 0.5V.

〔Effect of the invention〕

According to the present invention as described above, it is possible to easily automate testing of laser control circuits, reduce testing man-hours, and reduce costs.In addition, it is possible to easily replace the LD unit, and the light emitting power is always the specified power. This has the effect that a LD control method can be realized.

[Brief explanation of drawings]

Fig. 1 is a block diagram explaining the present invention in detail, Fig. 2 is a block diagram explaining the present invention in detail, Fig. 3 is a block diagram explaining the conventional example, and Fig. 4 shows the drive current of the laser diode. FIG. 5 is a diagram explaining the relationship between the amount of light emitted and FIG. 5 is a diagram explaining the monitor voltage. In the figure, 1 is the LD unit, 2 is the single current adjustment unit, and 3 is the LD unit.
is a read power level detection section, 4.7.14 is a D/A converter, 5 is a read power level current adjustment section, 6 is a write power level current adjustment section, 8 is a write power level setting section, 9.17 is a write power Level current difference setting section, 10
1 is a write power level current subtraction section, 11 is a level shift section, 12 is a PD current/voltage conversion section, 13 and 15 are analog switches, 16 is a converter, 21 is a switch, 31 is an operational amplifier, and゛) Oh 1y Ichi Rimira Hollow and Ito Hikari, lJ Iki 3 theory hood ■zu figure y64 figure τ Moni riden 14 and ? theory date month T5 figure 5 figure procedure amendment (self button Showa year month October 14, 1985 Patent Application No. 2 Catena No. 3 Relationship with the case of the person making the amendment Patent applicant address 1015 Kamiodanaka, Nakahara-ku, Yozaki City, Kanagawa Prefecture'
(522) Name: Fujitsu Ltd. 4, Agent: Address: 1015-8 Kamiodanaka, Nakahara-ku, Yozaki-shi, Kanagawa Prefecture, 1, Toru 1, of Bessatsu with amendments.
vinegar

Claims (1)

[Claims] 1) Light emission of a laser diode unit (1) that emits light at a read power level for reading data on a data recording medium and at a write power level for writing data on the data recording medium. This is a laser control method that compensates the current detection sensitivity of a monitoring photodiode (PD) with respect to power, so that a predetermined value of emitted light power can be obtained even if the laser diode units (1) each having unique characteristics are used. A photodiode current/voltage converter (12) that performs weighting and an analog/digital converter (16) that notifies the microprocessor of a predetermined photodiode voltage value automatically adjusts the light emission power so that it indicates a predetermined power when reading data. The first automatic power control means (3, 5
), a first analog switch (13) that turns on/off the laser diode unit (1), and a second auto power control means (8, an analog switch (9) for turning on/off the laser diode unit (17);
) and second auto power control means (8, 17
), the first and second analog switches (13, 15
), and the first digital/analog conversion means (4) at the read power level, and the second and third digital/analog conversion means (7) at the write power level.
, 14) A laser control method characterized by controlling with set values of . 2) Level control of the light emitting power of the laser diode unit (1) is performed by connecting the first auto power control means (3, 5) to the first analog switch (13).
The voltage-converted photodiode current is detected by the analog/digital conversion means (16), and the first photodiode current is turned off so that the light emission power of the laser diode unit (1) reaches the read power level. A laser control system according to claim 1, characterized in that the laser control system is controlled by digital/analog conversion means (4). 3) Auto power control during the data write operation is performed by turning off the second analog switch (15) and adjusting the photodiode current by the analog/digital conversion means (16) so that light emission at a specified level is performed. is controlled by the second digital/analog converting means (7) while monitoring, and then the second analog switch (15) is turned on to shunt the photodiode current corresponding to the write power level and calculate the difference. The current control of the subtraction means (10) is controlled by the third digital/analog conversion means (14).
A laser control method according to claim 1, characterized in that the laser control method is performed by: 4) The third digital/analog conversion means (14)
2. The laser control method according to claim 1, wherein the control target is a point at which the detected value of the analog/digital conversion means (16) reaches a read power level. 5) The laser control system according to claim 1, characterized in that when changing the write power level, the setting value of the second digital/analog conversion means (7) is changed proportionally. 6) The laser control method according to claim 1, wherein the light emitting power of the laser diode unit (1) is controlled in an off-focus or defocus state.